Proactive arc management of a plasma load

ABSTRACT

Proactive arc management systems and methods are disclosed. In many implementations, proactive arc management is accomplished by executing an arc handling routine in response to an actual arc occurring in the plasma load and in response to proactive arc handling requests in a sampling interval. The number of proactive arc handling requests in a sampling interval is a function of a proactive arc management count that in turn is a function of actual number of arcs in a preceding sampling interval. Accordingly during a present sampling interval proactive arc management executes arc handling for actual arcs in the present sampling interval and for each count in a proactive arc management count updated as a function of the number of arcs in the immediately preceding sampling interval.

FIELD OF THE INVENTION

This invention relates to arc management of a plasma load. More particularly it relates to managing a power supply and its arc management hardware to reduce arcs occurring in a plasma load.

BACKGROUND OF THE INVENTION

In DC (direct current) or LF (low frequency) plasma processing systems, arcs develop when charge builds up on a cathode. When the accumulated charge becomes large enough, an arc will occur from cathode to the anode or target material in the plasma chamber. Similarly in RF (radio frequency) plasma processing systems charge may build in areas of the chamber where there is a dielectric layer sufficient to support a charge. Again an arc will occur to discharge the accumulated charge on an element in the plasma chamber. If not extinguished quickly, arcs can be very detrimental to the plasma process and the quality of the processed film. All of these plasma processing systems, DC, LF and RF, are referred to herein as plasma loads.

There are numerous arc handling hardware techniques for extinguishing arcs in plasma loads. These techniques involve briefly interrupting power provided from the power supply to the plasma load. Some examples include shunting the current provided by the power supply away from the plasma load, dropping the voltage applied to the plasma load, reversing the voltage applied to the plasma load, switching voltage and current to accomplish one or a combination of the above techniques.

Most recently, arc management control has been added to arc handling as a technique to prevent arcs from occurring in plasma loads. One example of arc management is periodically interrupting or reversing power from the power supply to the plasma load. In effect the plasma load is periodically discharged to prevent arcs from occurring. This is very effective in reducing arcs, but slows the plasma process and raises the cost of the process.

SUMMARY OF THE INVENTION

In accordance many embodiments of this invention, is accomplished by executing an arc handling routine in response to an actual arc occurring in the plasma load and in response to proactive arc handling requests in a sampling interval. The number of proactive arc handling requests in a sampling interval is a function of a proactive arc management count that in turn is a function of actual number of arcs in a preceding sampling interval. Accordingly during a present sampling interval proactive arc management executes arc handling for actual arcs in the present sampling interval and for each count in a proactive arc management count updated as a function of the number of arcs in the immediately preceding sampling interval.

In accordance with other aspects, embodiments of the present invention relate to a system for proactive arc management in a power supply having a power module providing power to a plasma load through arc management hardware, and a digital power monitor module monitoring the present voltage and current supplied to the plasma load. An arc detect module compares a present voltage supplied to the plasma load to a preset voltage threshold and compares a present current supplied to the plasma load to a preset current threshold. The arc detect module generates an actual arc handling request when comparison of the present voltage to a voltage threshold or the present current to a current threshold indicates an arc is occurring in the plasma load. A proactive adjust module responds to actual arc handling requests from the arc detect module and provides a proactive arc management count that is a function of the actual arc handling requests received during a sampling interval. An arc management control module receives the proactive arc management count and controls the arc management hardware so that it executes an arc handling routine for each count in the proactive arc management count. The arc management control module also receives actual arc handling requests from the arc detect module and controls the arc management hardware so that it executes an arc handling routine for each actual arc handling request. This reduces the number of arcs in the plasma load to a minimum near or at zero while the plasma load operates with fewest possible proactive arc handling routines.

In accordance with still other aspects, embodiments of the present invention relate to a method of proactively managing power supplied to a plasma load to minimize the occurrence of arcs in the plasma load. The method begins by detecting an arc in the plasma load and sending an actual arc handling request when an arc in the plasma load is detected. The method continues by counting actual arc handling requests during a sampling interval to provide an actual arc count, and by updating a proactive arc management count as a function of the actual arc count. The method is completed by controlling the arc management hardware to execute an-arc handling routine to extinguish the arc in the plasma load in response to an actual arc handling request, and to discharge built-up charge in the plasma load in response to a proactive arc handling request for each count in the proactive arc management count.

In another aspect, an embodiment of the invention relates to a computer process running on a computing system or stored on computer readable media as an article of manufacture such as a computer program product. The computer program product may be a computer storage media readable by a computer system and encoding a computer program of instructions for executing a computer process for proactive arc management. The computer program product may also be a propagated signal on a carrier readable by a computing system and encoding a computer program of instructions for executing a computer process for proactive arc management.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the present invention are shown in the drawings. These and other embodiments are more fully described in the Detailed Description section. It is to be understood, however, that there is no intention to limit the invention to the forms shown in the drawings or described in the Detailed Description. One skilled in the art can recognize that there are numerous modifications, equivalents and alternative constructions that fall within the spirit and scope of the invention as expressed in the claims.

A more complete understanding of the present invention is apparent and more readily appreciated by reference to the following Detailed Description and to the appended claims when taken in conjunction with the accompanying Drawings wherein:

FIG. 1 is a system diagram of a power supply for a plasma load where the power supply incorporates proactive arc management of the plasma load;

FIG. 2 is a plot of arc rates verses time occurring in a unmanaged plasma load and a proactively arc managed plasma load;

FIG. 3 shows the flow of operations performed by the proactive arc management module of FIG. 1;

FIG. 4 shows the operational flow of arc detect module of FIG. 3;

FIG. 5 illustrates the flow of operations performed by the proactive arc management adjust module of FIG. 3; and

FIG. 6 shows the flow of operations performed by the arc management control module of FIG. 3.

DETAILED DESCRIPTION

FIG. 1 is a system diagram of a power supply 100 supplying power to a plasma load 106 and incorporating proactive arc management to protect the plasma load. The power supply 100 includes a power module 102, arc management hardware 104, analog-to-digital converter 108, digital signal processor 110 and proactive arc management module 112. In one embodiment the proactive arc management module 112 is implemented as a programmed computing system. The computing system includes a processor (not shown) and computer storage media (not shown) to store the program and provide working storage for the processor to execute the program. Computer storage media includes, but is not limited to, RAM, ROM, EPROM, flash memory or other memory technology. Alternatively, the proactive arc management module 112 might be implemented with logic circuits or programmable logic circuits.

Power module 102 provides a current “i” at a voltage “v” through the arc management hardware 104 to drive the plasma in the plasma load 106. The power applied to the plasma load 106 may be a DC (direct current), a LF (low frequency) or an RF (radio frequency). All of these applications of power are subject to arc discharges occurring in the plasma due to an imbalance in electrical charge built-up in the chamber during plasma-processing operations.

The arc management hardware 104 is used to extinguish arcs and to discharge built-up charge in the plasma load. Arcs may be managed by cutting off the power supplied to the plasma load. Examples of arc management include shunting the current away from the plasma load, turning off the power module, reversing the polarity of the power supplied to the plasma load. One example of a power supply with an arc management module to extinguish the arc is described in commonly assigned U.S. Pat. No. 7,514,935 B2, entitled System And Method For Managing Power Supplied To A Plasma Chamber, invented by Joshua Brian Paukratz, and issued on Apr. 7, 2009.

The monitor module 107, which includes analog-to-digital (A/D) converter 108 and digital signal processor 110, monitors the power supplied to the plasma load 106. The analog voltage “v” and current “i” passing from the arc management hardware 104 to the plasma load 106 is sensed and converted to a digital value by analog-to-digital (A/D) converter 108. Digital signal processor 110 processes the digital voltage “V” and digital current “I” from the A/D converter 108. The processing performed by digital signal processor 110 removes the polarity information (+/−) from voltage V and current I and passes their digital values to the proactive arc management module 112.

The proactive arc management module 112 also receives preset arc management settings 114 input into the memory of a programmed computing system implementing the proactive arc management module 112. These settings include a voltage threshold value V_(TRIP), a current threshold value I_(TRIP), a preset time duration T_(p) for all sampling intervals used by proactive arc management module, a preset arc management count C_(AM-PRESET), one or more preset index values N_(P) or index value functions, and a preset maximum arc rate A_(R-MAX). Depending on the power supply design and the plasma load, the duration T_(P) of the sampling time interval may be a few hundred milliseconds or a few hundred microseconds. The settings 114 are entered into and stored in memory that is part of the programmed computing system performing the operations of the proactive arc management module 112.

The proactive arc management module 112 uses V_(TRIP) and I_(TRIP) threshold values to detect the occurrence of an arc in the plasma load 106. When the voltage value V drops below V_(TRIP) threshold or the current value I spikes above I_(TRIP) threshold, either of these conditions indicate an arc is occurring in the plasma load 106. When there is an arc in the plasma load, there is a short circuit through the plasma load. The current drawn by the plasma load increases rapidly while the voltage across the plasma load decreases rapidly. In response to these conditions, the proactive arc management module 112 generates an actual arc handling request and passes it to the arc management hardware for every arc detected in the plasma load.

The proactive arc management module 112 also updates a proactive arc management count C_(AM) during a sampling time interval T_(M). The proactive arc management count C_(AM) is passed to the arc management hardware 104 to control the number of proactive arc handling requests in the next sampling time interval T_(M+1). The proactive arc management count is updated by the proactive arc management module summing the preset arc management count C_(AM-PRESET) with the actual arc count C_(A), (arcs occurring during present sampling interval T_(M)), and with the index value N. The index value N is adjustable as a function of the number of actual arcs, i.e. the actual arc count C_(A), in the present sampling interval T_(M).

The proactive arc management module 112 also detects its ability to control arc rate. If the actual arc count C_(A) in present sampling time interval T_(M) exceeds a preset maximum arc rate A_(R-MAX), the proactive arc management module 112 is no longer able to adjust the proactive arc management count C_(AM) sufficiently to control actual arcs. At this point the plasma load has to be renewed or cleaned. Accordingly, the proactive arc management module shuts down the power module 102 to turn off the power supply 100.

FIG. 2 is a graph of arc rate verses time illustrating the problem and the resulting proactive arc management provided by many embodiments of the present invention. An unmanaged arc rate 202 illustrates a typical arc rate over time exhibited by a low frequency plasma chamber containing target material and a substrate to be coated with the target material. The arc rate is at a nominal rate level if no arc management is used to prevent arcs. As the film deposition process continues and the target material is consumed, spikes 204 and 206 in the arc rate occur. Near the end of the useful life of the target material, the arc rate gradually increases as shown in region 208 of the unmanaged arc rate 202.

When proactive arc management is added to the power supply, proactive arc rate 210 illustrates how the proactive arc management rapidly reduces the arc rate to zero during region 212. Where the arc rate spikes 204 of unmanaged arc rate 202 occur, the proactive arc management module operates to allow only a minimal rise in the arc rate at bumps 214 and 216 of proactive arc rate 210 and otherwise holds the proactive arc rate at or near zero. In region 216, near the end of life of the plasma target material, the proactive arc rate 210 rises slowly. Finally in region 218 where the arc rates can no longer be successfully managed, the proactive arc rate rises rapidly, and the actual arc count C_(A) during a sampling interval exceeds the arc rate maximum threshold A_(R-MAX). When this happens, the pro-active arc management module 112 shuts down the power module 102.

The operation flow of proactive arc management module 112 (FIG. 1) is shown in FIG. 3. The logical operations of the various embodiments of the proactive arc management module may be implemented (1) as a sequence of computer implemented operations or computer program modules running on a computing system and/or (2) as interconnected machine logic circuits or programmable logic circuit modules. The implementation is a matter of choice dependent on the performance requirements of the module implementing the invention. Accordingly, the logical operations making up the embodiments of the present invention described herein are referred to variously as operations or modules. It will be recognized by one skilled in the art that these operations and modules may be implemented in software, in firmware, in special purpose digital logic circuits, programmable logic arrays and any combination thereof without deviating from the spirit and scope of the present invention as recited within the claims attached hereto.

In FIG. 3 the proactive arc management module begins with the get preset settings operation 302. Get preset settings operation 302 retrieves the preset settings—I_(TRIP), V_(TRIP), T_(P), C_(AM-PRESET), N (index functions or preset index values) and A_(R-MAX). Each of these preset settings are for processing parameters used by the proactive arc management module 112 in controlling the arc management hardware 104 (FIG. 1) to achieve the proactive arc rate 210 (FIG. 2). From the get operation 302 the operation flow passes to the arc detect module 304 and the proactive arc adjust module 306.

The arc detect module 304 uses the preset thresholds I_(TRIP) and V_(TRIP) to test for an arc condition in the plasma load. Module 304 compares I_(TRIP) and V_(TRIP) respectively to the current value I and the voltage value V received from digital signal processor 110 (FIG. 1). If the current value exceeds I_(TRIP) threshold or the voltage value V is less than V_(TRIP) threshold, an arc is occurring in the plasma load 106 (FIG. 1). When an arc condition is detected, the arc detect module 304 sends an actual arc handling request to the proactive arc adjust module 306 and to the arc management control module 308. Arc detect module 304 continues its arc detection operations until the power module 102 is shut down. When this occurs, the operation flow of the arc detect module returns to the main program flow of the computing system running the proactive arc management module operations.

The proactive arc adjust module 306 and the arc management control module 308 are operating in parallel with the arc detect module 304. Viewed from the perspective of the proactive arc adjust module 306, module 306 updates a proactive arc management count C_(AM) in the present sampling interval T_(M) that will be used in the next sampling interval T_(M+1) by the arc management control module 308. Viewed from the perspective of the arc management control module, it is controlling arc handling during the present sampling interval T_(M) based on a proactive arc management count C_(AM) generated in the previous sampling time interval T_(M−1). For example, assume the present sampling interval is T₂, then the C_(AM) updated during sampling interval T₂ will be used by arc control module 308 during sampling interval T₃. During the present sampling time interval T₂, the arc control module will use the C_(AM) generated by arc adjust module 306 during sampling time interval T₁.

The proactive arc adjust module 306 counts the number of arcs C_(A) occurring in the plasma load during the present sampling time interval T_(M) and updates a proactive arc management count C_(AM). To update C_(AM), the proactive arc adjust module adds the actual arc count C_(A) in the present sampling time interval T_(M) to the preset arc management count C_(AM-PRESET) and to an index value N which is a function of actual arc count C_(A). The proactive arc management count C_(AM) is passed to the arc management module 308 for use in that module during the next sampling interval T_(M+1). Each count of the proactive arc management count C_(AM) will cause the arc management control module 308 to execute a proactive arc handling operation. These proactive arc handling operations are proactive because they are triggered by each count of the proactive arc management count CAM rather than an actual arc handling request from the arc detect module 304.

The arc management control module 308 will execute an arc handling routine for two conditions. First, module 308 will execute arc handling routine for each proactive arc handling request. A proactive arc handling request is generated for each count in the proactive arc management count C_(AM) received from the proactive arc adjust module 306. Second, module 308 will execute arc handling routine when it receives an actual arc handling request from arc detect module 304. When the arc management operations complete at the end of present sampling time interval T_(M), the operation flow passes to arc rate test operation 310.

Arc rate test operation 310 compares the actual arc count C_(A) during the present sampling time interval T_(M) to a maximum arc rate threshold A_(R-MAX). If the arc rate threshold has not been exceeded, the operation flow branches NO and returns to get preset settings operation 302. The operation flow performed by proactive arc management then proceeds again in the next sampling interval T_(M+1) using updated values for the proactive arc management count C_(AM) from the sampling interval T_(M). If the A_(R-MAX) threshold has been exceeded, the operation flow branches YES to shut down module 312. Shut down module 312 turns off the power module 102 and stops the plasma process. The operation flow then returns to the main program flow operating the computing system (microprocessor and memory) in the power supply.

FIG. 4 shows the operations that may be performed by the art detect module 304 of FIG. 3, but it should be recognized that the operations described with reference to FIG. 4 may be carried out by implementations differing from the embodiments previously depicted. Operation flow of the arc detect module 304 begins with two parallel operations—get voltage operation 402 and get current operation 404. Get voltage operation 402 retrieves from digital signal processor 110 (FIG. 1) the voltage value V, which is the digital value of the analog voltage presently applied to the plasma load. This voltage is monitored by the A/D converter 108 and processed as digital value (magnitude only) by digital signal processor 110. Voltage test operation 406 detects whether the present voltage value V is less than the preset voltage threshold V_(TRIP). If the voltage V is not less than V_(TRIP), the operation flow branches NO and returns to get operation V to get an updated present voltage value V. The voltage test operation 406 then repeats. If the voltage V is less than V_(TRIP), the operation flow branches YES to send actual arc handling request operation 410. Send arc handling request operation 410 sends an actual arc handling request to the proactive arc adjust module 306 (FIG. 3) and to the arc management control module 308.

Get current operation 404 retrieves the digital current value of the analog current presently applied to the plasma load (e.g., from the digital signal processor 110 (FIG. 1)). This current is monitored by the A/D converter 108 and processed as a digital value I (magnitude only) by digital signal processor 110. Current test operation 408 detects whether the present current value I is greater than the preset current threshold I_(TRIP). If the current value I is not greater than I_(TRIP), the operation flow branches NO and returns to get current operation 404 to get an updated present current value I. The current test operation 408 then repeats. If the current I is greater than I_(TRIP), the operation flow branches YES to send actual arc handling request operation 410. Send arc handling request operation 410 sends an actual arc handling request to the proactive arc adjust module 306 (FIG. 3) and to the arc management control module 308.

The voltage threshold V_(TRIP) is preset as an indication of an arc occurring in the plasma load and is based on prior experience with the power supply and the plasma load. A typical value for V_(TRIP) threshold might be half of the nominal operating voltage V for the present power supply and plasma load. Likewise, the current threshold I_(TRIP) is preset as an indication of an arc occurring in the plasma load and is also based on prior experience with the power supply and the plasma load. A typical value for I_(TRIP) threshold might be an increase of 20% in the nominal operating current I for the power supply and plasma load combination. One skilled in the art will appreciate that thresholds V_(TRIP) and I_(TRIP) can be adjusted to adjust the sensitivity of the arc detection.

FIG. 5 is the operational flow of the proactive arc adjust module 306 in FIG. 3. As described earlier with reference to FIG. 3, the proactive arc adjust module updates the proactive arc management count C_(AM), which is given by the expression: C_(AM)=C_(AM-PRESET)+C_(A)+N. To update C_(AM), the proactive arc adjust module 306 uses the following presets: (1) duration T_(P) of the sampling interval, (2) preset arc management count C_(AM-PRESET), and (3) preset index functions or preset index values for index value N.

To determine actual arc count C_(A), the operational flow in FIG. 5 begins with count arcs operation 502. Count arcs operation 502 counts actual arcs occurring in the plasma load during each sampling interval. The receive arc handling request operation 504 receives an actual arc handling request from the arc detect module 304 (FIG. 3). Count arcs operation 502 increments actual arc count C_(A) by one each time an actual arc handling request is received. Sampling interval complete operation 506 detects the end of the sampling interval based on the preset interval duration T. If it is not the end of the sampling interval, the operation flow returns to count arcs operation 502. When the end of the sampling interval occurs, the operation flow branches YES from sampling interval complete operation 506 to zero arc count operation 508.

Zero arc count operation 508 detects whether the actual arc count equals zero. If arcs have occurred during the sampling interval, actual arc count C_(A) will be an integer and not zero. In this case the operation flow branches NO to set index operation 510 and thereafter to update C_(AM) operation 512. If the actual arc count is zero, the operation flow branches YES and bypasses set index operation 510 and update C_(AM) operation 512 so that the operation flow passes directly to send C_(AM) operation 514. Therefore when actual arc count C_(A) equals zero, the proactive arc management count C_(AM) that is sent is unchanged from the C_(AM) sent at end of previous sampling interval. Send C_(AM) operation sends the proactive arc management count C_(AM) to arc management control module 308 (FIG. 3).

When the actual arc count is not zero, set index operation 510 sets index value N as a function of actual arc count, i.e. f(C_(A)). A number of algorithms may be used when setting the index value N as a function of actual arc count C_(A). In one preferred embodiment the set arc index operation 510 uses a function that sets N to a value that is a percentage of the actual arc count, i.e. N=k % of C_(A), where “k %” is a percentage between 1% and 100%. In another embodiment the percentage may include values greater than 100%. Further different percentages might be stored and one percentage selected based on the actual arc count C_(A). In another embodiment, a single preset index value N_(P) might be used, or multiple preset index values N_(P) might be used and one preset index value selected based on the actual arc count C_(A). It will be apparent to one skilled in the art that any number of functions of C_(A) might be used to set the index value N. A chosen function should achieve zero actual arc counts in the plasma load as soon as possible with a minimum proactive arc management count C_(AM). Such a function reduces the total number arcs during the working life of the plasma load while at the same time minimizing the number of proactive arc handling operations.

Update operation 512 updates the proactive arc management count C_(AM) as a function of the actual arc count C_(A), i.e. C_(AM)=f(C_(A)). In one preferred embodiment, the function includes the preset arc management count C_(AM-PRESET), the actual arc count C_(A), and the index value N, which may also be a function of C_(A), and the C_(AM) function is the SUM of these three components, i.e. C_(AM)=C_(AM-PRESET)+C_(A)+N. Of course functions other than a summing function might be used. After the update operation 512 updates the proactive arc management count C_(AM), the operation flow passes to the send C_(AM) operation 514. Send C_(AM) operation 514 sends the proactive arc management count C_(AM) to arc management control module 308 (FIG. 3) and returns the operation flow to the arc management control module 308.

In FIG. 6 the operational flow for the arc management control module 308 of FIG. 3 begins at apply C_(AM) operation 602. Apply C_(AM) operation retrieves the proactive arc management count C_(AM) from memory and splits the sampling interval into subintervals spread over the present sampling time interval. In one preferred embodiment the apply C_(AM) operation 602 divides the preset duration T_(P) of a sampling interval (all sampling intervals have duration T_(P)) by the arc management count C_(AM) i.e. T_(p)/C_(AM). This splits the sampling interval into equal subintervals—one subinterval for each count in the arc management count. At the end of each subinterval, the apply C_(AM) operation 602 generates a proactive arc handling request. In another embodiment, the proactive arc handling requests are not evenly distributed over the sampling interval. The distribution of proactive arc handling requests over the sampling interval may be selected to match the propensity of the plasmas load to arc during the sampling interval.

Receive proactive arc handling request operation 604 receives the proactive arc handling request from the apply C_(AM) operation 602. Each proactive arc handling request is passed to execute arc handling operation 606. Similarly, receive actual arc handling request operation 608 receives an actual arc handling request if an arc occurs in the plasma load. The actual arc handling request comes from the arc detect module 304 (FIG. 3) and more particularly from the send actual arc handling request operation 410 (FIG. 4). If such an actual arc handling request is received, it is also passed to the execute arc handling operation 606.

In response to an arc handling request (actual or proactive), the execute arc handling operation 606 controls the arc management hardware 104 (FIG. 1) to execute an arc handling routine. Accordingly, an arc handling routine is executed during the sampling interval for any actual arcs. An arc handling routine is also executed in response to a proactive arc handling request even though at the time there is no actual arc in the plasma load. After the arc handling routine is executed, operation flow passes to last proactive request test operation 610 to detect if the last proactive request has been handled. If all the proactive requests have not been handled, the operation flow branches NO and returns to the execute operation 606 to await the next request—actual or proactive. When the last proactive request has been handled, the operation flow branches YES from last proactive request test operation 610 to return to the arc rate test operation 310 (FIG. 3).

In conclusion, the present invention provides, among other things, a system, method, and article of manufacture for proactive arc management of a power supply providing power to a plasma load. Those skilled in the art can readily recognize that numerous variations and substitutions may be made in the invention, its use and its configuration to achieve substantially the same results as achieved by the embodiments described herein. Accordingly, there is no intention to limit the invention to the disclosed exemplary forms. Many variations, modifications and alternative constructions fall within the scope and spirit of the disclosed invention as expressed in the claims. 

What is claimed is:
 1. A proactive arc management module in a power supply having a power module providing power to a plasma load through arc management hardware, and a digital power monitor module monitoring the present voltage and current supplied to the plasma load, said proactive arc management module comprising: arc detect module comparing a present voltage supplied to the plasma load to a preset voltage threshold and comparing present current supplied to the plasma load to a preset current threshold and generating an actual arc handling request when comparison of the present voltage or present current to the voltage threshold and current threshold, respectively, indicates an arc is occurring in the plasma load; proactive arc management adjust module responsive to actual arc handling requests from the arc detect module and providing a proactive arc management count as a function of the actual arc handling requests received during a sampling interval; and arc management control module responsive to the proactive arc management count and to actual arc handling requests to control the arc management hardware to execute an arc handling routine for each proactive count and each actual arc so that arcs in the plasma load are reduced to a minimum while the plasma load operates at maximum efficiency.
 2. The proactive arc management module of claim 1 wherein said proactive arc management adjust module comprises: a counting module responsive to the arc detect module and counting arcs occurring in the plasma load during a sampling interval to provide an actual arc count for the present sampling interval; index module for setting an index value; and update module responsive to a preset arc management count, the actual arc count and the index value and updating the proactive arc management count as a function of the preset arc management count, the actual arc count and the index value to provide the proactive arc management count for the next sampling interval.
 3. The proactive arc management module of claim 2 wherein the arc management control module comprises: apply module responsive to the proactive arc management count and sending a proactive arc handling request for each count in the proactive arc management count and distributes the proactive arc handling requests over the sampling interval; and execute module responsive to actual arc handling requests from the arc detect module and responsive to proactive arc handling requests from the apply module and controlling the arc management hardware to execute each arc handling request whether proactive or actual.
 4. The proactive arc management module of claim 2 wherein the index module sets the index value as a percentage of the actual arc count.
 5. The proactive arc management module of claim 2 wherein the index module sets the index value to a preset index value.
 6. The proactive arc management module of claim 2 wherein the update module updates the proactive arc management count by summing the preset arc management count, the actual arc count and the index value.
 7. A method for proactively managing power supplied to a plasma load to minimize the occurrence of arcs in the plasma load, said method comprises: detecting an arc in the plasma load and sending an actual arc handling request when an arc in the plasma load is detected; counting actual arc handling requests during a sampling interval to provide an actual arc count; updating a proactive arc management count as a function of the actual arc count; and controlling the arc management hardware to execute an-arc handling routine to extinguish the arc in the plasma load in response to an actual arc handling request, and to discharge built-up charge in the plasma load in response to a proactive arc handling request for each count in the proactive arc management count.
 8. The method of claim 7 wherein said updating comprises: setting the index value as a function of the actual arc count; and summing the preset arc management count, the actual arc count and the index value to update the proactive arc management count.
 9. The method of claim 8 wherein said setting sets the index value as a percentage of the actual arc count.
 10. The method of claim 8 wherein said setting sets the index value to a preset index value.
 11. The method of claim 8 wherein said updating comprises: detecting whether the actual arc count during the present sampling interval is zero; and when the actual arc count is zero, bypassing said setting and said updating to proceeding directly to said controlling so that the proactive arc management count provided said controlling in the next sampling interval is the same as the proactive arc management count provided during the present sampling interval.
 12. The method of claim 11 wherein said controlling comprises: distributing the counts of the proactive arc management count over the sampling interval to provide proactive arc handling requests distributed over the sampling interval; and executing an arc handling routine for each proactive arc handling request and for each actual arc handling request.
 13. The method of claim 12 wherein said distributing comprises: dividing the sampling interval by the proactive arc management count to split the sampling interval into subintervals; and providing a proactive arc handling request at the end of each subinterval.
 14. A computer program product readable by a computing system in a power supply providing power to a plasma load and encoding a computer program of instructions for executing a computer process for proactive arc management of the power supply and plasma load, said computer process comprises: comparing a voltage value and a current value to a voltage threshold and a current threshold, respectively, to detect an arc in the plasma load; generating an actual arc handling request when an arc in the plasma load is detected; counting actual arc handling requests during a present sampling interval (T_(M)) to generate an actual arc count (C_(A)) for the present sampling interval (T_(M)); updating a proactive arc management count (C_(AM)) as function of a preset arc-management count (C_(AM-PRESET)), the actual arc count (C_(A)) for the present sampling interval am), and an index value (N) equal to a function of the actual arc count (C_(A)); and controlling arc management hardware to execute an-arc handling routine during the next sampling interval (T_(M+1)) in response to an actual arc handling request occurring during next sampling interval (T_(M+1)) and in response to the proactive arc management count (C_(AM)) from present sampling interval (T_(M)), the arc handling routine discharges accumulated charge in the plasma load when executed.
 15. The computer process of the computer program product of claim 14 further comprises: detecting whether the actual arc count (C_(A)) for the present sampling interval (T_(m)) is zero; when the actual arc count (C_(A)) for the present sampling interval (T_(M)) is not equal to zero passing the computer process flow to said updating; and when the actual arc count for the present sampling interval (T_(M)) is zero, passing the computer process flow directly to said controlling so that the proactive arc management count (C_(AM)) provided said controlling in the next sampling interval (T_(M+1)) is the same as the proactive arc management count provided during the present sampling interval (T_(M)).
 16. The computer process of the computer program product of claim 15 wherein said updating comprises: setting index value (N) equal to a function of the actual arc count (C_(A)); and summing the preset arc management count (C_(AM-PRESET)) plus the actual arc count (C_(A)) plus the index value (N) to update the proactive arc management count (C_(AM)) for the next sampling interval (T_(M+1)).
 17. The computer process of the computer program product of claim 16 wherein said setting sets (N) equal to a percentage of actual arc count (C_(A)).
 18. The computer process of the computer program product of claim 16 wherein said setting sets (N) equal to a selected one of a plurality of preset index values (N_(P)) where the selected index value depends upon the actual arc count (C_(A)).
 19. The computer process of the computer program product of claim 15 wherein said controlling comprises: distributing the counts of the proactive arc management count (C_(AM)) over the present sampling interval (T_(M)) to provide proactive arc handling requests distributed over the sampling interval; and executing an arc handling routine for each proactive arc handling request and for each actual arc handling request.
 20. The computer process of the computer program product of claim 19 wherein said distributing comprises: dividing a preset duration (T_(P)) of the sampling interval by the proactive arc management count (C_(AM)), i.e. (T_(P)/C_(AM)), to split the sampling interval into subintervals; and providing a proactive arc handling request during each subinterval. 